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In agricultural grasslands, management practice highly determines reproductive success for ground-nesting bird species. The most effective conservation measure is the delay of first mowing dates until broods fledge or bird friendly mowing. Late mowing often implies economical losses for farmers and may increase land use abandonment, which will, in turn, cause habitat deterioration. Thus, grassland bird conservation involves the challenge to protect broods against land use and to promote an appropriate management to sustain habitat quality at the same time. Because of their late and extended breeding season Corncrakes Crex crex are in particular vulnerable to frequent mowing which increases nest destruction, chick mortality and habitat loss.
This thesis aims to gain knowledge on favourable habitat characteristics and brood protection in relation with grassland management to derive implications for the conservation of Corncrake breeding sites in floodplain meadows. Study area is the Lower Oder Valley National Park in northeastern Germany that holds a Corncrake population of 50 to 250 calling males. The study covered two study periods, before (1998-2000) and after (2012-2015) the implementation of new Corncrake conservation measures allowing inferences on the effects of different timing and intensity of mowing for brood protection and habitat conservation.
Breeding was only confirmed on meadows with high forb cover, low sedge cover, low litter heights and a close location to ditches. Radio-tracked females preferred areas with high cover of forbs (> 30%) and a distinct relief heterogeneity, which was associated with increased vegetation diversity. Vegetation characteristics on sites with day calling activity of males showed more similarity with breeding sites than with sites only used for nocturnal calling, supporting the assumption that diurnal calling indicates the occurrence of females. Favoured vegetation structure was best provided by mowing in the preceding year. Low-intensity grazing was less effective in reducing litter and sedge cover, especially when conducted late in the season. In the absence of management, meadows rapidly overgrow and dense litter accumulates from dead plant material in eutrophic floodplains, which increases walking resistance for Corncrakes and may impede prey accessibility. Plant species richness and forb cover declined after land use cessation. Male Corncrakes abandoned calling sites on meadows unmanaged for longer periods.
Besides the availability of suitable nesting sites, food supply and nest predation risk are also related to vegetation structure and may indirectly influence the habitat quality. Faecal samples of Corncrakes consisted mainly of beetles and their larvae, followed by snails, spiders and earthworms. Invertebrate biomass, sampled with pitfall-traps, was twice as high, the numbers of large ground beetles even five times higher on previously unmanaged than on managed meadows. Invertebrate abundance was highest in the first and second years after land use abandonment, but strongly decreased afterwards to a similar level like under annual management. Therefore, unmown refuge strips for Corncrake protection and alternating mowing also enhance invertebrate prey resources in floodplain meadows.
Mammals caused the majority of all observed artificial ground nest predations. Nest predation risk was higher on previously unmanaged than on managed sites. Unmanaged meadows probably attract mammalian predators, because they provide a more favourable vegetation structure for foraging and harbour high numbers of small rodents, increasing also the risk of incidental nest predations. These findings suggest that an annual removal of vegetation, if conducted late in the season to protect grassland birds may reduce predation risk of ground nests in the subsequent year.
Whereas during 1998-2000 half of the study area was managed by the end of July, land use was delayed on meadows occupied by Corncrakes until at least 15 July or 15 August during 2012-2015. On meadows mown between 15 July and 15 August refuge strips were applied. The majority of Corncrake broods were started in the second half of May and mowing postponement until 15 August allows 80% of chicks to fledge without disturbance in the study area. In 65% of broods chicks reach independence (> 14 days old) until 15 July and can be protected by Corncrake friendly mowing because then they are large enough to successfully escape during mowing. Both adults and chicks survived in 10 m wide refuge strips. Because most birds tried to leave the unmown block for the first time when it was up to 30 m wide and only 15 to 30 m wide strips served as temporary habitat for unfledged chicks from mowing to departure, 10 m should be considered as the absolute minimum width for refuge strips.
The strong reduction of land use especially during July should have allowed more chicks to survive until fledging in 2012-2015 than 1998-2000. Besides the protection of nests and higher chick survival, the decline of mowing intensity increased the extent of habitat available for second breeding attempts. In 2012-2015, broods were initiated until late July in the study area. Male Corncrakes showed continuous arrival and departure during the breeding season. Similar departure rates were estimated by a multi-state occupancy model and for radio-tracked males in the same study area and periods, which both left their home ranges spontaneous and due to the impact of mowing. Compared to 1998-2000, total departure of males during June and July was reduced by 50% in 2012-2015, when more calling sites were protected from mowing. Although male Corncrakes show high intra-seasonal dispersal due to their sequential polygamous breeding system, postponed land use should have increased mating opportunities and re-nesting at first breeding sites.
Therefore, future directions of Corncrake conservation in eutrophic floodplains should address the increase of annual late mowing to protect broods and maintain favourable habitat conditions by creating a more flexible mowing regime adjusted to actual occurrence of Corncrakes. This requires expert advice to farmers based on an intense monitoring of calling Corncrakes. Repeated nocturnal surveys during May and June are highly recommended because low detection probability in combination with constant departure substantially underestimated the number of males present. Additionally, diurnal calling activity could improve the identification of breeding sites and timing could be used to estimate chick age in July to select sites for Corncrake friendly mowing. Because currently late mowing dates are unattractive for farmers conservation actions should along with financial compensations for mowing after 15 August promote the utilization of late-cut grass with poor nutrient quality for combustion. Energy production could provide an alternative income for farmers operating in conservation areas with delayed land use dates and will increase their acceptance of Corncrake protection measures.
American and European foulbrood (AFB and EFB) are devastating bacterial brood diseases of honey bees (Apis mellifera), which cause colony and economic losses worldwide. The causative agent of AFB, Paenibacillus larvae, are grouped into different ERIC-genotypes (Enterobacterial repetitive intergenic consensus) the two most common of which are ERIC I and ERIC II. In the field, the differentiation between the symptoms of AFB and EFB (caused by Melissococcus plutonius) can be difficult. The differentiation between the ERIC-genotypes in the field based on the symptoms is not possible at all. The differentiation between the ERIC-genotypes of P. larvae during diagnosis can help to understand the spread of the AFB disease. Hence, a tool capable of detection and distinction between the bacterial brood diseases and the P. larvae-genotypes is needed. For the optimal prevention of disease spread, the diagnosis needs to be fast, cheap and reliable.
This study focuses on the development of a diagnostic sandwich ELISA and a lateral flow device (LFD) for the detection and distinction of EFB and AFB, including the differentiation of the two main occurring P. larvae genotypes. The therefore necessary specific monoclonal antibodies (mAbs) were obtained by immunizing mice with M. plutonius or P. larvae strains belonging to either ERC I or ERIC II. The generated mAbs were characterized for their specificity towards the target bacteria and for their cross reactivity towards other bee-associated bacteria. The screening for suitable mAbs resulted in two specific mAbs against M. plutonius, two against P. larvae in general and two against ERIC II. In combination with the anti-P. larvae mAbs, the anti-ERIC II mAbs were used for genotyping.
In order to evaluate the suitability of the mAbs, their antigens were identified. The target antigens of the produced mAbs turned out to be proteins that could be of further interest as they seem to be involved in the pathogenesis and host-pathogen-interaction. The mAbs with the same antigens were used in the sandwich ELISA for testing the cross reactivity and strain detection. Suitable mAb combinations were used for LFD production. The LFDs were then successfully tested against several field isolates of AFB and EFB causing agents and no cross reactivity with bee-associated bacteria was detected. The P. larvae strains used for mAb testing were genotyped to obtain information about the respective genetic variance. In the process atypical P. larvae strains were identified and further characterized using the generated mAbs. The ability of the mAbs to also recognise the atypical strains as well indicates that the mAbs bind to an antigen that is common among different P. larvae strains.
All in all, a fast tool for detection and differentiation of EFB, AFB and the two ERIC-genotypes was developed that has to be further tested for its reliability in the field.
Emerging infectious diseases are among the greatest threats to human, animal and plant health as well as to global biodiversity. They often arise following the human-mediated transport of a pathogen beyond its natural geographic range, where host species are typically not well adapted due to a lack of co-evolutionary host-pathogen dynamics. One such pathogen is the fungus Pseudogymnoascus destructans (Pd), which causes White-Nose disease in hibernating bats. While Pd was first observed in North America where it has led to mass-mortalities in some bat species, the pathogen originates from Eurasia where infection is not associated with mortality. Most of the Pd research has focused on the invasive North American range, which likely underestimated the genetic structure of the pathogen and the role it might play in the disease dynamics.
In my work, I therefore evaluated the genetic structure of Pd in its native range with the aim of uncovering cryptic diversity and further use population genetic data to address some key ecological aspects of the disease dynamics. With an extensive reference collection of more than 5,000 isolates from 27 countries I first demonstrated strong differentiation between two monophyletic clades across several genetic measures (multi-locus genotypes, full genome long-read sequencing and Illumina NovaSeq on isolate pools). These findings are consistent with the presence of two cryptic species which are both causative agents of bat White-Nose disease (‘Pd-1’, which corresponds to P. destructans sensu stricto, and ‘Pd-2’). Both species exist in the same geographic range and co-occur in the same hibernacula (i.e., in sympatry), though with specialised host preferences. I further described the fine-scale population structure in Eurasia which revealed that most genotypes are unique to single hibernacula (more than 95% of genotypes). The associated differences in microsatellite allele frequencies among hibernacula allowed the use of assignment methods to assign the North American isolates (exclusively Pd-1) to regions in Eurasia. Hence, a region in Ukraine (Podilia) is the most likely origin of the North American introduction.
To gain further insights into the spatial and temporal dynamics of White-Nose disease on a localised scale, several hibernacula were sampled with high intensity (artificial hibernaculum in Germany and natural karst caves in Bulgaria). Low rates of Pd gene flow were observed even among closely situated hibernacula. This indicates that Pd does not remain viable on bats over summer or it would be frequently exchanged among bats (and hence hibernacula) resulting in a homogenous distribution of genotypes. Instead, bats need to become re-infected each hibernation season to explain the yearly re-occurrence of White-Nose disease. Given the distribution and richness of Pd genotypes on hibrnacula walls and infected bats of the same hibernacula, bats become infected from the hibernacula walls when they return after summer. This means that environmental reservoirs exist within hibernacula (i.e., the walls) on which Pd spores persist during bat absence and which drive the yearly re-occurrence of White-Nose disease. In an experimental setup, I confirmed the long-term viability of Pd spores on abiotic substrate for at least two years and furthermore discovered temporal variations in Pd spores’ ability to germinate. In fact, these variations followed a seasonal pattern consistent with the timing of bats absence (reduced germination) and presence (increased germination) and could indicate adaptations of Pd to the bats’ life-cycle. The infection of bats from environmental reservoirs hence seems to be a central aspect of White-Nose disease dynamics and Pd biology.
Pds ability to remain viable for extended periods outside the host increases its risk of being anthropogenically transported and might have played a role in the emergence of White-Nose disease in North America. The existence of a second species (Pd-2) poses a great additional danger to North American bats considering that its introduction there could lead to deaths and associated population declines in so-far unaffected species given what is known about differing host species preferences in Eurasian bats. Even within the native range of Pd, the movement of Pd between differentiated fungal populations could facilitate genetic exchanges (e.g., through sexual reproduction) between genetically distant genotypes. Such genetic exchanges could lead to phenotypic jumps in pathogenicity or host-species preferences and should hence be prevented.
The native range of a pathogen holds great potential to better understand the genetic and ecological basis of a (wildlife) disease. My work informs about the dangers associated with the accidental transport of Pd (and other pathogens) and highlights the need for ‘prezootic’ biosecurity-oriented strategies to prevent disease outbreaks globally. Once a pathogen has arrived in a new geographic range, and particularly if it has environmentally durable spores (as demonstrated for Pd), it will be difficult/impossible to eradicate. Furthermore, a pathogen’s ability to remain viable outside the host and infect them from environmental reservoirs has been associated with an increased risk of species extinctions and needs to be considered when designing management strategies to mitigate disease impact.
For decades, evolutionary biologists have sought to understand the evolution of individual behaviour, physiology and ecology allowing organisms to cope to environmental change. One of the main challenges of current climate change is the unprecedent rate of temperature increase, as well as the increased occurence of extreme heat events. Interindividual response variability opens a whole new area of opportunities to understand how individual phenotypic traits are linked to individual response differences. In colour polymorphic species, colour honestly reflects an individual’s life-history strategy, and each morph may, therefore, represent an alternative life-history strategy. As such, colour polymorphic species, such as the Gouldian finch (Erythrura gouldiae), may be good models to assess how different strategies between morphs are linked to their espective responses to environmental variations. However, polymorphic species have mainly been disregarded for that purpose. In this context, the main aim of this thesis was to understand how the two morphs of the Gouldian finch respond through phenotypic plasticity to simulated heatwaves reaching thermocritical temperatures, and whether such differential responses may help to identify a ‘winner’ and a ‘loser’ morph in the light of climate change. To address these issues, we used an integrative approach including measurements of behavioural (Study 1), physiological (Study 2), and reproductive (Study 3) parameters. The novelty of our approach was to assess the immediate behavioural and physiological response variation of individuals of the two morphs longitudinally across different thermal conditions, as well as the postponed effects of this thermocritical heatwave exposure on their reproductive performance. In this study, although the behavioural responses generally did not differ between morphs or according to temperature intensity, the physiological and reproductive parameters differed in response to morph and temperature intensity. Blackheaded females, in particular, seem highly sensitive to thermocritical heatwaves, as they exhibited decreased body mass and increased oxidative damage during the thermocritical heatwaves, and advanced breeding initiation after these conditions, whereas these variables remained mostly unaffected in black-headed males and red-headed individuals. However, despite some response differences between morphs, both invested similarly in reproduction following intense heatwaves, and the offspring of both morphs were similarly affected. Based on these results, no morph therefore seems to appear more disadvantaged than the other following an intense heatwave, and red- and black-headed Gouldian finches may both be considered as climate stress ‘losers’.
The impact of inbreeding under different environmental conditions and of artificial selection on cold tolerance was investigated in laboratory populations of the tropical butterfly Bicyclus anynana. The investigation focused on (1) the effects of inbreeding on several fitness-related traits and whether inbred individuals are more susceptible to stress, (2) interactions between inbreeding, genetic adaptation to cold stress and environmental conditions, (3) the effects of artificial selection and inbreeding in the adult stage in other developmental stages, and (4) the effect of inbreeding depression on the heat shock response. Environmental conditions are not constant over time; consequently organisms have to deal with environmental changes. Besides naturally fluctuating conditions, human-induced climate change may increase temperature changes as well as the severity of heat or cold waves. Temperature-stress resistance describes an organism’s ability to cope with stressful temperatures. Enhanced resistance to temperature stress can be reached by phenotypic plasticity or genetic adaptation. Plastic organisms are able to react fast to changing environmental conditions, whereas genetic adaptation is more important for long-term adaptation. Natural habitats may also be affected by human impact, causing habitat loss or fragmentation and changes in population structure. A decrease in the population size may result in inbreeding and inbreeding depression (ID). Consequences of inbreeding are well documented, and inbred individuals are predicted to be more sensitive to environmental stress than outbred individuals. The long term persistence of species and populations depends on their ability to adapt to novel conditions which in turn depends on genetic diversity. Therefore, studies of temperature resistance and its evolution in relation to inbreeding are very important. First a higher susceptibility of inbred individuals to environmental stress was determined in different populations of B. anynana. Inbreeding depression was revealed for several fitness-related traits, but not for immunity traits or heat tolerance. Temperature affected most traits, revealing the importance of temperature on ectotherms; just two hours of thermal stress affected important reproductive, life-history and immunity traits already. Importantly though, no evidence were found that inbred individuals are more susceptible to stressful temperatures than outbred individuals. Genetic adaptation and phenotypic plasticity can interact with one another, resulting in genotype-environmental interactions (G x E). The hypotheses tested here were that some genotypes are more plastic than others and that lines with increased cold stress resistance are less plastic with regard to cold resistance than control lines. To induce plastic responses the exposed lines differed in cold tolerance and inbreeding to different temperatures as well as different feeding regimes and measured fitness-related traits. Several interactions were detected in which a selection regime was involved, but these interactions did not show a clear overall pattern. In summary though, findings were that marginal impacts of directional selection and inbreeding on plastic responses and suggest that, at least for my study organism, the genetic architecture of fitness-related traits is not connected with the architecture of plastic responses. The next investigation concerned with the manifestation of genetic adaptation to produce one specific phenotype across development stages and possible trade-offs. The assumption tested was that there is a genetic link between different developmental stages to produce one definite phenotype by imposing selection in the adult stage only. Lines selected for increased cold resistance in the adult stage were used and increased cold resistance throughout all developmental stages was expected. However, higher cold resistance was found only in the adult stage and not in developmental stages. This could be either the result of a resource allocation trade-off between different stages or that there is no cold resistance phenotype. Thus, if selection takes place in the adult stage it does not affect the others. In the last experiment investigation was directed to determine whether there are negative inbreeding effects on the heat shock protein (HSP) response. Under stressful conditions, organisms produce the HSPs and they act as chaperons required for refolding and repairing of stress degraded proteins. Testing was oriented to find if inbreeding as a genetic stressor´ provokes a higher HSP expression and if there is evidence for higher temperature stress susceptibility on inbred individuals. Findings indeed showed a stronger HSP up-regulation in control compared to inbred lines with a negative inbreeding impact occurrence, which may causally underlie inbreeding depression.
The need for the diversification of utilised species has emerged in the present aquaculture
production environment. Shifts in consumer interest, climate change-induced temperature
increases, and major fish disease outbreaks have put a strain on this industry. In this context,
the pikeperch (Sander lucioperca) has become a new target species for aquaculture in Central
Europe. This new aquaculture focus species exhibits high numbers of offspring, fast growth,
and high consumer acceptance. It can also effectively deal with higher temperatures and turbid
water. However, the rate of successful rearing is still low, as various developmental
transformations and environmental effects commonly lead to high mortality rates during the
early ontogenetic stages. The aim of this doctoral project was thus to obtain insight into
embryonic to larval developmental changes during pikeperch ontogeny. Specifically, the times
of change that influence survival were of focus. Based on the available literature, particular
attention was paid to general growth patterns and the connected developmental changes, the
determination of myogenesis gene marker expression changes, and the support of animal
welfare efforts for pikeperch rearing procedures. To achieve the aims of the study, a methodical
setup consisting of morphometric and developmental observations was combined with
transcriptome gene marker analysis for the different ontogenetic stages.
Three developmental phases were differentiated during the embryo-larval transition. Each of
these possessed distinct growth patterns with different growth rates. The intermediate
threshold phase showed internal organ development that focused on digestive, neuronal, and
heart tissues. Three activity phases of myogenesis were determined: during early embryonic
development, before hatching, and after hatching during the larval stages. Therefore, muscle
development seemed to be regulated to balance energy expenditures. Additionally, two
coinciding skeletogenic phases were found. Furthermore, a cell line from whole embryos was
developed to support the replacement of animals in future experimental setups. A software
system for video analyses was developed to support rearing procedures in aquaculture
facilities. This prototype can be used to automate the counting of specimens and thus allows
for faster responses to increasing mortalities. Based on the results of this thesis project, further
insights into the early development of pikeperches were obtained. This will facilitate the design
and adaptation of raising and husbandry protocols, which can help to further establish
pikeperch as an aquaculture species and support its application in modern recirculatory
systems.
The goal of this thesis was to study the systematic relationships within the superfamily Sylvioidea (Aves: Passeriformes) in general and within the closely related families Acrocephalidae and Locustellidae in particular, by means of DNA sequences. Sylvioidea itself and families therein were the focus of many studies based as well on morphological characters as on DNA. Due to their morphological similarity and their presumably rapid radiation most studies failed to solve relationships between sylvioidean families and also demarcations of single families and relations within are still in progress. In this study, an enlargement of previous datasets, both taxa and number of DNA sequences, and more sophisticated analysis methods were used to improve the resolution in Sylvioidea, Acrocephalidae and Locustellidae. In addition, the applicability of barcoding in Acrocephalidae was tested. The monophyly of Sylvioidea could be supported and the families Paridae and Remizidae, which were sometimes still included, clustered among the outgroup taxa. Four families, Nicatoridae, Panuridae, Alaudidae, and Macrosphenidae constitute basal splits within Sylvioidea. The division of the former sylviid/timaliid clade in five families, Sylviidae, Leiothrichidae, Pellorneidae, Timaliidae, and Zosteropidae was supported. Scotocerca, Erythrocercus, and Hylia, previously supposed to be members of Cettiidae, were shown not to belong to this family. As the three genera are also morphologically and ecologically different, they were here proposed to be elevated to family rank, Scotocercidae, Erythrocercidae and Hyliidae, respectively. The family Acrocephalidae consisted of the four genera, Nesillas, Acrocephalus, Hippolais, and Chloropeta. In the analysis for this thesis, the latter three appeared to be non-monophyletic. One Acrocephalus species, A. aedon was sister to a clade containing four species of Hippolais as well as two out of three Chloropeta species. They were all merged in the genus Iduna, based on the DNA evidence and shared morphological and ecological characters. Iduna had priority over Hippolais or Chloropeta according to the International Code of Zoological Nomenclature. The one remaining Chloropeta species (C. gracilirostris) had to be renamed to Calamonastides as Chloropeta was no longer available for this taxon. Seven genera were included in the re-analysis of the family Locustellidae: Locustella, Bradypterus, Megalurus, Dromaeocercus, Schoenicola, Cincloramphus, and Eremiornis. Apart from the monotypic genera Dromaeocercus and Eremiornis and Schoenicola, of which only one species was included, the remaining genera were found to be non-monophyletic. One clade contained all Locustella species, Megalurus pryeri and all Asian/Oriental Bradypterus species. All species in this clade were synonymized with Locustella, as the type species of Locustella was included, whereas the type species of Bradypterus fell in a different clade. Therefore, the remaining African Bradypterus species retained their genus name, and Dromaeocercus was renamed to Bradypterus as it clustered within Bradypterus. Cincloramphus, intermingling with the remaining Megalurus species, was synonymized with the latter. Barcoding, growing in popularity for delimiting species, was tested in its applicability for Acrocephalidae. Fourteen taxa currently recognized as full species would fall under the 2% threshold of sequence divergence proposed for delimiting species using the mitochondrial cytochrome b gene. It was also shown that it is important to clarify which part of a DNA sequence is used, as different parts can give different results regarding the 2% threshold. In addition, the choice of “complete deletion” or “pairwise deletion” in calculating genetic distances is important, if incomplete are sequences used.
Global climate change is omnipresent all over the world and is affecting and challenging organisms in various ways. Species either have to adapt to the changing environmental conditions or move to new habitats in order to avoid extinction.
Possible ways for an organism to react can be dispersal, phenotypic plasticity, genetic adaptation or a combination of these factors. Among the various consequences of climate change, especially changes in temperature affect plenty of species. In ectotherms, the body temperature and associated mechanisms are strongly dependent on environmental conditions.
The aim of this work was to investigate the mechanisms underlying adaptation to thermal variation and heat stress in the widespread butterfly species <i>Pieris napi<i>.
Focusing on indicators of individual condition, including morphology, physiology and life history traits, the purpose was to specify whether the species’ responses to temperature variation have a plastic or genetic basis. In the first experiment, phenotypic variation along a latitudinal and altitudinal cline was investigated. Yellow reflectance of wings was negatively correlated with wing melanisation, providing evidence for a trade-off between a sexually selected trait (yellow color) and thermoregulation (black color). Body size decreased with increasing latitude and led to the assumption that warmer conditions are more beneficial for <i>P. napi<i> than cooler ones. An increased flight performance at higher altitudes but not latitudes may
indicate stronger challenges for flight activity in high-altitude environments.
The second experiment focused on clinal variation and plasticity in morphology, physiology and life history in F1-generation individuals reared in captivity at different temperatures. It could be shown that individuals from cooler environments were less heat-tolerant, had a longer development but were nevertheless smaller, and had more melanised wings. These differences were genetically-based. Furthermore, it could be shown that a higher developmental temperature speeded up development, reduced body size, potential metabolic activity, and wing melanisation but increased heat tolerance, documenting plastic responses.
In a third experiment, we examined physiological responses to heat stress. A transcriptome analysis revealed an upregulation in molecular chaperones under hot conditions, whereas antioxidant responses and oxidative damage remained unaffected. The antioxidant glutathione (GSH) though was reduced under both cold and hot conditions. Interestingly, Swedish individuals were characterized by higher levels of GSH, lower early fecundity, and lower larval growth rates compared with German or Italian populations, suggesting a ‘pace-of-life’ syndrome. Thus, the individuals from warmer regions show the opposite pattern with a lower investment into maintenance but a faster lifestyle.
In summary, we found clinal variation in body size, growth rates and concomitant development time, wing aspect ratio, wing melanisation and heat tolerance. The effects of high developmental temperature very likely reflect adaptive phenotypic plasticity. When speeding up development; heat tolerance is increasing while body size, potential metabolic activity and wing melanisation are decreasing. Overall, body size of <i>P. napi<i> individuals decreased from south to north while the melanisation of the wings increased. Furthermore, we found a connection between increased wing melanisation and decreased yellow reflectance, most likely caused by a trade-off between the two. We could confirm that <i>P. napi<i> individuals from warmer environments were more heat-tolerant and larger than individuals from colder environments. Due to increasing temperatures and heat waves becoming more frequent in the future, being able to cope with such conditions will be advantageous. As warmer conditions had positive effects on individual development, <i>P. napi<i> may benefit from global warming, but its association with moist habitats suggests negative consequences of climate change. We could also reveal pronounced plastic and genetic responses in <i>P. napi<i>, which may indicate high adaptive capacities. Thus, increasing temperature may not be too problematic for the species, as it seems to be rather well equipped to deal with such challenges. However, as climate change entails changes in precipitation / humidity along with temperature changes, such issues need further investigation.
Deflected by the barrier function of topographical structures such as high mountain ranges, open water bodies or desert, migrating birds concentrate at certain points or corridors referred to as ‘bottlenecks’. An area like this was discovered at Mount Besh Barmag (Azerbaijan) in autumn 2007, but the data gathered during a four-week survey was insufficient to do more than hint at the existence of a major bird migration bottleneck. Therefore, a comprehensive bird migration study was conducted to analyse the magnitude of this potential bottleneck site. The study covers the periods from August to mid-November 2011 and from March to the end of May 2012 and includes daily counts at three observation points focusing on three different migrant types: passerine, waterbirds and soaring birds. In addition, a sound recorder with an omnidirectional microphone collected bird migration calls by both day and night. In total, 278 bird species were observed in an estimated passage of 1,239,369–1,514,267 diurnally migrating individuals in autumn 2011 and 646,733–817,183 individuals in spring 2012. Fifteen species passed through the study area in numbers exceeding 1% of their world populations and 34 species in more than 1% of their flyway populations in at least one of the observation periods. 84% of the observed migrating birds in autumn 2011 and 95% of them in spring 2012 passed through at heights below 50 m above ground exposing them imminently to the danger of collision with obstacles. In the analysis of nocturnal sound recordings, 119 bird species were identified of which 106 were expected to occur as migrants, and calculated estimates revealed the occurrence of 108,986 calls in autumn 2011 and 33,348 calls in spring 2012. The volume of diurnal bird migration emerging from the data with respect to species number and number of individuals is certainly a strong indication of the existence of a major bird migration bottleneck at Besh Barmag. On account of methodological constraints, the high number of night flight calls can only hint at a nocturnal bird migration bottleneck and confirmatory research aided by visual methods (radar, thermal imaging) is necessary to back up the acoustic results. The Besh Barmag bottleneck offers a great opportunity to establish a standardised long-term monitoring programme to investigate avian population dynamics in the vast and little known Eurasian landmass. Acoustic-based monitoring might be a cost-effective method, but it is limited to a few vocally prolific species only. The aim should rather be the establishment of a bird observatory as already successfully installed in a number of European bird migration bottlenecks.
Bats spend half of their life at roosting sites. Hence, exploring for potential roosts is an essential task for their survival, especially for those species which switch roosts regularly, such as several temperate bat species. However, localizing new roosts is a difficult task due to bats’ sensory limitations (e.g., vision, echolocation range). To compensate such constrains, it has been hypothesized that bats rely on cognitive processes like associative learning, spatial memory, social information use and memory retention for an efficient roost localization. However, no previous study has assessed these cognitive skills under natural conditions.
The aim of my thesis was to assess how individually RFID-marked, free-ranging bats use different cognitive processes when localizing suitable day roosts. For this purpose, I used a pairwise roost-quality (suitable vs. unsuitable) choice experiment with automatic monitoring and assessed bats’ cognitive processes according to different cues available. Cues were echo-reflective (spectral signature of boxes), spatial (position of the box within the experimental pair) and social (presence of conspecific at roosts), each one linked to a different cognitive process.
I found that Bechstein’s bats (Myotis bechsteinii) used associative learning to discriminate between suitable and unsuitable newly placed boxes according to their echo-reflective cues. However, when individuals returned to known suitable roosts, they relied more on spatial memory to localize them. This was evidenced by the higher proportion of visits to the unsuitable boxes after swapping box positions within the same experimental pairs. When social cues were available, bats discovered a higher number of suitable roosts and re-localized previously occupied roosts more accurately. Taken together, Bechstein’s bats used multiple cognitive processes and prioritized one process over another depending on the relevance of the cues and search context.
Memory retention of the learned association was analyzed one year later, after the bats had returned to their breeding sites from their hibernacula. I found no evidence that individuals remembered the association between roosts’ suitability and their respective echo-reflective cue. The lack of memory retention could be attributed to hibernation or the duration of the period that the bats spent away from their summer habitat without the opportunity to reinforce the association contingencies. Nevertheless, bats quickly relearned the same association in a short period of time. This emphasizes the high behavioral flexibility of the bats.
Given the ability of Bechstein’s bats to quickly learn to discriminate roosts based on their external echo-reflective cue via associative learning, I investigated whether the use of echo-reflective cues improves box detectability and further occupancy. This was also assessed in free-ranging Natterer’s (Myotis nattereri) bats and the brown long-eared bats (Plecotus auritus). I found that the use of echo-reflective cues did not improve the detectability and occupancy of newly placed boxes despite the previous experience of the colonies with such cues. There were differences among species in the number of discovered boxes, visits and roosting days. These differences could be related to the species-specific explorative behavior and roost-switching behavior. Box supplementations programs aimed to conserve or relocate bat colonies should consider these behaviors to increase their likelihood of success even when bat colonies are used to roosting in artificial shelters.
My research underlined the importance of evaluating multiple cues under natural conditions to understand how natural selection has shaped the cognitive process used for localizing resources. Cognitive field studies are logistically challenging given the number of factors to control. However, automatic monitoring techniques like the one used in this study give the possibility to deepen the understanding of the cognitive ecology of animals. I finally discuss two venues of further research to understand the spread of information within colony members about novel roosts and the recruitment dynamic to novel roosts.
Analysis of partial migration strategies of Central European raptors based on ring re-encounter data
(2018)
The phenomenon of partial migration in birds in
which some individuals of a population are migratory while others stay in the breeding area is of increasing scientific interest. The strategies of partial migratory raptors from Central Europe are, however, unclear for most species. We analysed ring re-encounter data of Common Kestrels Falco tinnunculus, Eurasian Sparrowhawks Accipter nisus and Common Buzzards Buteo buteo ringed in Germany in terms of distances and directions between ringing and re-encounter sites. We investigated possible differences between sexes and age classes, as well as effects of ringing region, seasonal weather (in the form of North Atlantic Oscillation indices) and long-term temporal changes (including climate change) on migratory strategies by means of generalized linear models. We found that migration is mostly conducted by juveniles, although migratory adults were also found. In general, males tend to migrate less than females and juveniles less than adults.
Kestrels showed differences between age classes and sexes and they responded to weather in summer and autumn. The migration activities of Kestrels decreased over years. Sparrowhawks from different regions showed no differences in migration activity and no responses to long-term temporal changes. They did not respond to seasonal weather either. Buzzards showed strong responses to winter weather (‘winter escapes’) predominantly in highland regions, and a reduction of migratory intensity probably due to global warming.
The explanatory power of ringing data, however, is limited by low re-encounter rates and temporal and spatial heterogeneity in re-encounter probability. Spatial heterogeneity mainly depends on the distribution of observers as well as on their willingness to report a re-encountered ring to the corresponding ringing scheme. We analyzed a data set of ringing and re-encounter data of Kestrels, Buzzards and Sparrowhawks provided by the EURING Data Bank. We calculated monthly re-encounter rates across Europe and, for different time periods, we predicted re-encounters for individuals of these species ringed in Germany, on the assumption that re-encounter probabilities are evenly distributed at the highest value observed within the respective home ranges. Subsequently, we tested for correlation between re-encounter rates and human population density. The number of predicted re-encounters exceed the observed by 50-300 %. We found differences between monthly re-encounter rates and between different prediction periods. Distances (between ringing and re-encounter sites) differ significantly between observations and predicted re-encounters, with higher distances in predictions. Correlation between re-encounter rates and human population density is significant, but correlation coefficients are low (ρ = 0.291-0.511). Correcting for observer heterogeneity can help to analyze ring re-encounter data e.g. in terms of dispersal and migration. However, a comprehensive data collection and a digitalization of possible prior data records by the respective ringing schemes may allow advances in this method even further.
Costs of reproduction. A demographical approach to examine life-history trade-offs ─ Abstract. Resource-allocation trade-offs are fundamental constraints of life-history evolution. In particular the trade-offs between reproduction and longevity and between present and future reproduction are expected to form reproductive patterns. Unfortunately, exploring such trade-offs in natural populations is complicated and may not be possible. In face of several limitations, zoo data appear to be useful to better understand the reproductive biology of endangered, rare or cryptic species. In the first step, it was sought after with a data-mining, comparative multi-species approach for broad patterns of correlations between lifespan and variables in bird-eating spiders (Theraphosidae). The subfamily Eumenophoriinae on average lived longest, followed by the Theraphosinae, Ornithoctinae, Grammostolinae, Selenocosmiinae, Ischnocolinae and finally the Avicularinae. Species inhabiting tropical, more humid and/or low-altitude environments lived longer, suggesting that more predictable environments favour the evolution of longer lifespans. Furthermore, large range size, low abundance, sub-terrestrial life-style, and aggressive behaviour were all linked with longer lifespans. An argument for resource allocation trade-offs was found as larger spiderling and prosoma size were negatively related to longevity. In the second step, a demographical approach has been applied for two old-world deer species (Vietnamese sika deer Cervus nippon pseudaxis, Mesopotamian fallow deer Dama dama mesopotamica). In both species, births peaked right before the onset of the rainy season in natural environments. Females reached high reproductive output earlier in life and had (in one species only) higher survival rates than males. Offspring number covaried positively rather than negatively with longevity. In females, the length of the reproductive phase correlated positively with longevity, birth rate within the entire lifespan, and offspring number, while it was negatively correlated to the birth rate during the reproductive phase (in one species). The length of the post-reproductive phase was positively related to longevity and negatively to birth rate during the entire lifespan. In the third section, life-histories of Asiatic (Equus hemionus ssp.) and African wild asses (Equus africanus ssp.) have been anlaysed in a comparative way with another demographical long-term approach. All taxa showed even in captivity peak birth rates during the periods of highest food availability in their natural environments. Sex-specific survival rates with females living longer than males were evident in Kulan and Onager but not in Kiang and Somali wild ass, pointing towards different life-history strategies even among closely related taxa. Females achieved their highest reproductive output earlier than males, which is typical for polygynous mating systems. Offspring number and longevity were rather positively correlated than negatively. Taken together evidence for reproductive trade-offs was weak, though the length of the reproductive period was negatively related to birth rates within the reproductive period. Birth intervals increased with female age, probably reflecting detrimental effects of senescence.
Most animals live solitarily, but for some species the benefits of group living outweigh the costs and social communities have evolved. Truly social societies are characterized by cooperation in tasks like foraging, predator defense and brood care. In the most extreme cases, non-reproducing individuals act as helpers and provision offspring of reproducing individuals at the cost of their own reproductive success. This alloparental care is attributed to kin selection that provides the helpers with inclusive fitness benefits. However, how reproductive role is determined and in which ways virgin helpers in a group benefit the community is not always well understood.
Spiders are known to be generalist hunters, which in many cases do not shy away from cannibalism. Thus, most spiders live solitarily. However, in a few species a permanently social lifestyle has evolved in which individuals live together throughout their life, providing an intriguing case of social evolution. These spider communities are characterized by lack of premating dispersal leading to extreme inbreeding, by reproductive skew, in which only a proportion of females reproduce and by cooperative breeding of the reproducing females. It has been assumed that the large proportion of virgin females act as helpers not only in foraging and web maintenance but also during brood care. In the social spider Stegodyphus dumicola brood care involves the intensive task of regurgitation feeding, at which mothers regurgitate their own liquefied body tissue. At the end of brood care, the offspring sucks the mothers dry during matriphagy, leading to the death of brood caring females and a semelparous lifestyle. In the closely related solitarily breeding Stegodyphus lineatus virgin females do not provide brood care. The ability of virgin females in S. dumicola to care for offspring would thus depict an adaptation to sociality and cooperative breeding. I therefore aimed to clarify the role and significance of virgin females in colonies of social spiders and furthermore investigated a possible mechanism of how reproductive role within a colony is determined.
I investigated whether there is differential task participation in a non-reproductive task and the task of brood care among reproducing mothers and virgin females (helpers) in Stegodyphus dumicola. The study provides explicit evidence that brood care – including egg sac care, regurgitation feeding and matriphagy – is performed by mothers as well as by virgin helpers. Virgin females in a colony can thus rightfully be termed allomothers. However, the task participation differed between the reproductive states. While mothers engaged more often in brood care, virgin females were more active in foraging. However, the active provisioning of offspring by the virgin females decreases the motherly workload as is suggested by the extended brood care period in comparison to solitary breeders. The observations on virgin allomaternal care are supported by histological studies on the midgut tissue of brood caring females, which revealed that mothers and virgin helpers undergo comparable morphological changes in preparation of regurgitation feeding. The changes in virgin females correlate to ovarian development that might depict an internal maturation process which sets virgin females in the right state to provide care. The morphological changes in mothers and virgin helpers of S. dumicola are less comprehensive than in the solitarily breeding S. lineatus mothers. This indicates that cooperatively caring females are able to save on their resources, provision offspring for longer and thus are probably able to increase survival of the brood by an extended care period. A surprising consequence of cooperative brood care is the ability of mothers to produce a second viable egg sac, even when the first brood is successful. Mothers of the cooperative breeding S. dumicola can thus depart from the strictly semelparous lifestyle and instead invest part of their resources in a second clutch. This finding identified a new way of how cooperative breeding enhances breeding success of reproducers and thus inclusive fitness for helpers as well, thus adding to the benefits of allomaternal care.
Virgin females did not store significantly lower amounts of lipids in their midgut tissue than mothers, raising the question of how much reproductive role of females is determined by competition for resources during growth, as often assumed. Another possible determinant of female reproductive skew is the characteristic male scarcity in spider colonies, with only about 12 percent of spiders being male. Males are assumed to mature early within a few days and die early, thus leaving late maturing females unmated due to lack of mating partners. However, my studies provided evidence that male maturation is more skewed than expected and males might survive several months. Subadult females did not accelerate molting when an adult male was present, which could further indicate, that male presence is not a limiting factor on reproduction in males. Furthermore, males are able copulate with up to 16 females and did not show e preference for large females during mating trials. Males are thus able to fertilize all females, provided all females mature in time. I therefore suggest, that male scarcity is not major determinant of reproductive skew in females, especially in small and middle-sized colonies in which female maturation might only be moderately skewed.
My studies were able to demonstrate the meaning of the large proportion of unmated females in a colony of the social spider S. dumicola. Virgin helpers support mothers during brood care and thus do not only enhance the brood care period but facilitate mothers to produce multiple clutches. Virgin females are able to care as they undergo similar morphological changes as mothers’ do. This seems to be facilitated by an internal maturation process, indicated by ovarian development and oviposition by virgin females, both of which has never been observed in virgins of the subsocial species. How reproductive role is determined remains unclear, but I was able to exclude male scarcity as a major factor influencing reproductive skew.
Midges are small mosquitoes that can transmit pathogens to susceptible hosts through their blood-sucking act. They are known as biological vectors that can transmit the bluetongue virus (BTV) and the Schmallenberg virus (SBV) to ruminants, among others. Various vector control measures can be used to curtail the spread of the virus during an epidemic. However, for effective vector measures, it is essential to have profound knowledge of the role of biting midges as vectors, as well as their biology and phenology. For several years, midges were not in the focus of research and there are still considerable gaps in knowledge. Therefore, the present work examines various aspects of biting midges of the genus Culicoides, whose function as vectors of the Schmallenberg virus was already proven at the beginning of the project.
The aim of the first part of this work was to determine the percentage of infected midges in various German areas in order to determine the influence of Culicoides midges within the virus epidemic. For this purpose, samples, collected during 2011 and 2012 as part of monitoring projects, were analysed. Additionally, in early 2013, various farms in southern and eastern regions of Germany, where SBV was considered to be largely absent, were equipped with UV traps. The small number of virus-positive samples did not allow a more precise assessment of the viral spread in culicoid midges. Instead, it revealed the importance to conduct targeted samplings of its vectors during an acute outbreak. Additionally, the presented results and statements made by several animal owners, gave reason to believe, that SBV must have affected the southern and eastern parts of Germany earlier than actually assumed. This would consequently have led to an increased immunity in host animals, which provides a reasonable explanation for the low positive values and is in agrement with the statements made by various farmers.
The second part of this work identifies the conditions and surrounding factors under which acute SBV diseases emerged in ruminants in the cold winter months of 2012/2013. After the diagnosis of several acute SBV infections of sheep in a sheep pen in Mecklenburg-Western Pomerania, culicoid midge activity could be proven. This demonstrates that, suitable conditions for its vectors given, an infection of SBV can also take place during wintertime. A more detailed analysis of the surrounding conditions revealed, that the outdoor temperatures during infection were consistently at values of at least 5-9 ° C for several consecutive days, which enabled the flight and blood-sucking activity of the midges within
the shelter.
Midge activity during wintertime represents a crucial component in understanding how the virus can outlast the cold season. A constant midge presence could lead to a low but permanent infection rate throughout the cold months, enabling a recurrence of the pathogen the following year. Instead, a longer vector-free timeperiod would point to other mechanisms that allow the virus to re-occur in Germany on a yearly basis. Thus, the acute cases of SBV infections in sheep rose the question of critical threshold temperatures, representing the beginning of midge activity. The investigation of several stables sheltering cattle, horse or sheep addressed potential differences between indoor and outdoor activity and whether the type of host animal has an influence on the beginning of the flight. In the third part of this work, a long vector-free period and several differences in the onset of midge activity between different types of host animals could be detected. It could also be illustrated that the progression of the flight began differently depending on the present type of host animal/type of stable. For all cattle stables and the sheep barn the first midge activity was measured indoors, whereas for horses, culicoid midges were found to become active either at the same time or almost simultaneously inside and outside the animal shelters. This suggests that the horse stables do not represent good breeding sites for midges, which might be attributed to husbandry practices. In addition, it was possible to determine specific threshold temperatures for the different types of host animals and for various midge species. Altogether, the late beginning of flight, measured at the beginning of March, was surprising. This raises more questions of alternative mechanisms enabling the virus to outlast the winter months. The documentation of species-specific threshold temperatures can be a useful tool f.i. within automated large stables to keep indoor temperatures under the threshold value in order to postpone the onset of culicoid activity of various vector species. This may help to prevent virus transmissions during winter or to evoke a delay in spring, making it more difficult for the virus to overwinter.
To be able to start instant defense measures during an ongoing virus epidemic, which is transmitted by Culicoides midges, reducing the ground-living midge larvae offers a promising option during the warm season. For targeted vector control measures, it is important to know the breeding sites of culicoid midge species. Therefore, four agriculturally used biotopes were sampled and compared to four biotopes of a forest-dominated area. The results clearly show that meadows per se are not suitable breeding habitats for Culicoides
spp. Only the influence of livestock animals induces their potential as developmental sites. The various biotopes of the forest-dominated region were less subject to anthropogenic influences. Although fewer individual midges were found here, it displayed a higher biodiversity than the agricultural habitats. These results demonstrate once more the potential of forests in regards to the preservation of biodiversity. In Particular, the alder on fen site revealed most midge species and also the highest number of collected specimens among the studied biotopes. That illustrates the high impact of this specific humid type of habitat in respect to species diversity and the need of its perpetuation.
As part of this work, new breeding sites for a variety of culicoid species were identified and assigned to the usually rather short profiles of known Culicoides species. For one part, previous observations of chosen substrates could be consolidated. Furthermore, new breeding substrates were identified. Additionally, information of abiotic factors such as ph-value, soil moisture or organic compound of all sampled breeding substrates obtained from a soil analysis, extended the knowledge about the species-specific choice of breeding habitats and their characteristical traits. The additional knowledge about potential breeding substrates and their soil factors might be useful for future epidemiological modelling approaches. It can also raise the effectiveness and accuracy of targeted vector control measurements during an epidemic outbreak. Therefore, it may indirectly contribute to the preservation of endangered rare species. However, there is still an enormous need for more research before this goal can be fully achieved.
In holometabolic insects, senescence starts at sexual maturation and condition diminishes with age. Young virgin males should gain the highest mating success. Although sperm quality and quantity typically decreases with age, older males have been shown to have a higher mating success in a variety of insect taxa. Life-history theory predicts an increased aggressive and persistent courtship behaviour, due to a decrease of the residual reproductive value and thus, the opportunity for future reproduction. In the butterfly Bicyclus anynana, older males gain up to a 4x higher mating success despite a poorer condition, compared to younger males. As older males were found to court more often and for longer time bouts,suggesting a higher intrinsic motivation, there is evidence for the residual reproductive value hypothesis. On the other hand, an age-specific variation of male sex pheromones may provide females with information, being helpful to chose specific males. The latter could be males which have proven a high fitness in terms of survival, thus essentially reflecting a “good genes" hypothesis. This doctoral thesis investigated the reasons underlying old male mating advantage in B. anynana. The first study tested whether old male mating advantage prevails, even if females were unable to distinguish between older and younger males. The results were backed up by examining female rejection rates, male courtship frequency, courtship duration, time to copulation and mating duration. Older males had a significantly higher mating success compared to younger ones regardless of differences in pheromone blends or the females ability to smell. Older males courted more often and longer. The results support the residual reproductive value hypothesis. Study 2 investigated post-copulatory sexual selection in B. anynana. Females were double-mated, allowing for sperm competition and cryptic mate choice. Older males had a higher paternity success than younger ones, when the former were the last mating partner. The paternity success was balanced across age classes when older males were the first mating partner. Older males transferred larger spermatophores with higher numbers of eupyrene sperm than younger males. B. anynana does not exhibit cryptic mate choice and last-male precedence is the most probable fertilization pattern. The higher proportion of offspring sired by older males is due to significantly increased numbers of fertile sperm compared to younger males. The latter are clearly disadvantaged, as the higher sperm numbers provided by older males counteract the benefits of last-male precedence. Study 3 explored determinants of mating success in B. anynana. Successful males had longer wings, a heavier thorax, a lighter abdomen, a higher fat content, and higher phenoloxidase expression levels. Mating success seemed to be directly linked to proxies of flight performance. Successful males showed a better flight performance, in turn increasing mating success. As energy reserves are of crucial importance for flight manoeuvres, they may play a significant role in male mating success. Study 4 tested the effects of male age and mating number on spermatophore mass, sperm number, male oxidative status, and reproductive success by manipulating age and mating frequency in male B. anynana. Spermatophore mass and sperm numbers increased significantly with age, while antioxidant defences and oxidative damage declined. Female fecundity and egg-hatching success was highest when being mated with young virgin males. Antioxidant defences decreased with age, being a possible reason for the negatively affected reproductive success in females. Ejaculate quality diminished with age and mating number, despite larger spermatophores and higher sperm numbers being found in older males. Therefore, spermatophore size and sperm numbers can not be considered as reliable proxies of male condition. The final study proofed whether male sex pheromone comprise honest signals and which traits might be associated with increased pheromone titres. Pheromone titres were analysed among successful and unsuccessful males when being mated with either a control or a scent-blocked female. Both groups did not differ in pheromone levels. Successful males had significantly higher numbers of eupyrene sperm. No correlation between male pheromones and any investigated trait was found, suggesting that pheromone titres do not provide reliable information on male quality. Nothing indicates that male sex pheromones in B. anynana play a decisive role in female mate choice. Successful males generally have a better body condition, resulting in a more vigorous courtship behaviour and higher sperm numbers. Hence, variation in body condition rather than pheromone titres is more likely to determine male mating success. Mating decisions are primarily driven by male behaviour. The results suggest that old male mating advantage arises from sexual conflict.
Solifuges (Solifugae, Arachnida) are an important element of the fauna especially in arid and desert environments. Unfortunately, this animal group has only been extremely poorly studied not only in terms of morphology, but also ecology, physiology, systematics and phylogeny. The present study aimed to provide a detailed overview of their anatomy and ultrastructure. Representatives of these peculiar animals were investigated by means of light and electron microscopy in order to gain new insights in their functional morphology and also to evaluate potential characters for their systematic and future phylogenetic studies. The histology and ultrastructure of the following organ systems have been investigated: tarsal structures, sensory structures and nervous system, coxal glands, alimentary system, respiratory system, circulatory system and reproductive systems. Additionally, a camel spider in Baltic amber was described, representing the second known specimen of fossil Solifugae in Baltic amber. Further on, the entire mitochondrial genome of Nothopuga sp. was sequenced for comparison with other solifuges and chelicerates in order to reveal changes in their gene order.
Under natural conditions, most parts of northeastern Germany would be covered by forests that would be dominated by beech (Fagus sylvatica) and oak (Quercus robur and Q. petraea). However, today most of the wooded area is covered by artificial monocultures of pine forests. This form of cultivation was recognised to be the cause of instability against calamities of pests as well as severe storms therefore in the early eighties of the last century this knowledge was used to start the conversion of the forests towards more nature-like stands. The ecological effects of the forest conversion on the soil, the fauna and the flora have been investigated in a nation-wide project supported by the Federal Ministry of Education and Research (BMBF) in the project “Future-oriented forest management”. The present work has been accomplished within the scope of this project and is concerned about the effects that different aspects of forest conversion have on oribatid mites. The present work shall serve to answer a number of questions about the distribution of oribatid mites and their reaction to environmental changes. The investigation was carried out on 12 plots in two sampling areas. 7 plots were chosen in the Müritz NP and 5 in Eberswalde. In both areas plots were chosen that resemble the different stages of forest conversion: one medium aged pine plot in each area, two medium aged mixed plots with pines and beeches in the Müritz NP and one mixed plot in Eberswalde as well as one beech plot in each area. Furthermore, in the Müritz NP the chance arose to investigate the effects of different age stages of the stands on the oribatid mites. Therefore, an additional young pine plot and two old mixed plots have been sampled. In Eberswalde, on the other hand, another emphasis was laid on the effects of a different nutrient content in the soil. Here, an additional pine plot and mixed plot, respectively, of a higher trophotopic level was sampled. In Eberswalde, an additional sampling was done in three plots (a beech plot, a mixed plot and a pine plot) to investigate the horizontal distribution of the oribatid mites in these habitats. The data were used along with others to ecologically characterise the different species. The sampling took place from 2000 to 2002. Within the scope of the doctoral thesis, 392 samples were analysed. 122 samples from one year from the Müritz NP and 270 samples from three years from Eberswalde were analysed. Altogether 155,450 oribatid mites from 82 taxa were found in these samples. The ecological characterisation of the species revealed that the various species react quite differently to the investigated factors. Most species occur with different abundances in different forest types, but their abundance often varies also in comparable stands of both sampling areas. This indicates that they react to climatic effects as well as to biotic and abiotic factors. The forest conversion from pine forests to beech forests causes the abundance of oribatid mites to decrease, probably due to the change of the humus form from mor or mor-like moder in pine forests to mull in beech forests, that is accompanied by a decrease of the abundance of fungi, the main food source for most oribatid mites. Furthermore, the species composition changed. Species like Camisia spinifer, Adoristes ovatus or Acrogalumna longipluma that are typical for pine forests disappeared, while other species like Achipteria coleoptrata or Chamobates voigtsi immigrated in mixed stands after the introduction of beeches. The age of the stands proved to be another important factor. The overall abundance of oribatid mites was higher in the older stands than in the younger stands, while the percentage of juvenile oribatids decreased towards the older stands. Furthermore, the dominance structure became more uneven and shifted toward a higher percentage of fungivorous oppiid and suctobelbid mites. Especially on the old mixed plots, Oppiella nova reaches a dominance value of about 60 %. The nutrient content of the soil seems to be a relatively unimportant factor on the community level as no significant differences with regard to overall abundance and the dominance structure could be recorded. However, the Canonical Correspondence Analysis showed that the nutrient content of the soil does influence the distribution of species, at least with regard to their individual abundance. In summary, it can be said that the distribution of the oribatid species is influenced by many factors, and the stocking is only one of these factors. Nevertheless, a group of four species could be established, that can be used as indicators for the success of the forest conversion towards more nature-like deciduous forests: Achipteria coleoptrata, Autogneta longilamellata, Chamobates subglobulus and C. voigtsi.
In the thesis the reason for the low breeding success of white rhinos in captivity was investigated and solutions suggested. It was also investigated how to improve management of free ranging populations. It was establish whether female white rhinoceros choose their mates and, if so, which factors influence their choice. The study also seeks to establish whether there is any relationship between androgens, environmental factors and mating activity. The study was carried between March 1997 and May 1999 on a private game farm in South Africa. The study animals enjoyed conditions similar to those enjoyed by free-ranging populations. A non-invasive endocrine monitoring technique was developed to assess the androgen concentrations in faeces of male white rhinos. The body and horn size of adult males was measured, the concentration of testosterone in their faeces determined, and the characteristics of their territories investigated. All of these factors were then set in relation to their reproductive success. The reproductive success was established by genetic analysis of fatherhood using AFLP methods. The quality of male territories was described by vegetation structure, tree and grass species composition, the availability of frequently foraged or selected grass species as well as the nutritional composition of the forage. In addition, the influence of seasonal rainfall, presence of receptive females and territorial activity on androgen metabolite concentrations was established.
Amid the current global biodiversity crisis, being able to accurately monitor the changing state of biodiversity is essential for successful conservation actions and policy. Despite the pressing need for reliable and cost-effective monitoring methods, collecting such data remains extremely difficult for elusive species, such as temperate zone bats. Although bats are important indicators of environmental changes, monitoring bat populations is challenging because they are nocturnal, volant, small, and highly sensitive to human activities and disturbance. Thus far, population trends of temperate zone bats have been mainly based on visual surveys, including winter hibernation counts at underground sites. However, as bats may not always be roosting in visible locations within the hibernacula, it is currently unknown how these estimates relate to actual population sizes.
Infrared light barriers combined with camera traps are a novel method to monitor bats at underground sites. When installed at the entrance of hibernacula, infrared light barriers have the potential to estimate site-level population sizes more accurately than visual surveys, by counting all bats flying in and out of the site. Moreover, camera traps, consisting of a digital camera and white flash, can be used for species-level identification. However, for this new method to be applicable as a large-scale bat monitoring technique, it is important to characterize it with regard to three main criteria: is the method minimally invasive, is it accurate, and is it scalable in terms of spatial and temporal resolution? Therefore, the purpose of this thesis was to investigate the invasiveness and accuracy of this novel bat monitoring method, and to develop standardized and automated data analysis pipelines, both for the light barrier and camera trap data, to support the deployment of this method at scale.
In Publication I, we used light barrier data, infrared video recordings and acoustic data from an experimental field study to investigate whether the white flash of the camera trap has any measurable short- or long-term effect on bat activity and behavior. The flash of the camera trap was turned on and off every week at each site, which allowed us to compare the activity and behavior of bats between flash-on and flash-off nights. We found that despite the high sensitivity of bats to disturbance, they did not change their nightly activity patterns, flight direction, echolocation behavior, or long-term site use in response to the white flash of the camera trap. Based on these results, we concluded that camera traps using a white flash are a minimally invasive method for monitoring bat populations at hibernacula, providing high quality images that allows species-level identification.
In Publication II, we used infrared video surveillance to quantify the accuracy of infrared light barriers, and we described a standardized methodology to estimate population sizes and trends of hibernating bat assemblages using light barrier data. We showed that light barrier accuracy varies based on the model and location of the installation relative to the entrance, with the best combination achieving nearly perfect accuracy over the spring emergence phase. When compared to light barrier-based estimates, we found that visual counts markedly underestimated population sizes, recovering less than 10% of the bats at the most complex hibernacula. Moreover, light barrier-based population trends showed regional patterns of growth and decline that were not detectable using the visual count data. Overall, we established that the light barrier data can be used to estimate the population size and trends of hibernating bat assemblages with unprecedented accuracy and in a standardized way.
In Publication III, we described a deep learning-based tool, BatNet, that can accurately and efficiently identify bat species from camera trap images. The baseline model was trained to identify 13 European bat species or species complexes using camera trap images collected at 32 hibernation sites (i.e., trained sites). We showed that the baseline model performance was very high across all 13 bat species on trained sites, as well as on untrained sites when the camera angle and distance from the entrance were comparable to the training images. At untrained sites with more atypical camera placements, we demonstrated the ability to retrain the baseline model and achieve an accuracy comparable to the trained sites. Additionally, we showed that the model can learn to identify a new species, while maintaining high classification accuracy for all original species. Finally, we established that BatNet can be used to accurately describe ecological metrics from camera trap images (i.e., species diversity, relative abundance, and species-specific phenology) that are relevant for bat conservation.
We conclude that infrared light barriers and camera traps offer a minimally invasive and accurate method to monitor site-level bat population trends and species-specific phenological estimates at underground sites. Such remote data collection approaches are particularly relevant for monitoring large, complex hibernation sites, where traditional visual surveys are not feasible or account only for a small fraction of the actual population. Combining this automated monitoring method with a deep learning-based species identification tool, BatNet, allows us quickly and accurately analyze millions of camera trap images resulting from large-scale, long-term camera trap studies. As a result, we can gain unprecedented insights into the behavior and population dynamics of these enigmatic species, drastically improving our ability to support data-driven bat conservation.
Recent climate change and its consequences for living organisms constitute one of the greatest problems of our century. Global warming entails an increase in mean temperature and the frequencies of extreme weather events. Those changes in environmental conditions affect both plants and animals. Because of their inability to escape from unsuitable environments, plants have evolved a wide spectrum of molecular programs to protect themselves against changing conditions. Responding on altered environmental conditions will change plants chemical composition and therefore also affect plants interaction with other species (e.g., predator-prey or symbiotic relationships). For instance, changes in the chemical composition of plants may influence the survival of associated herbivores. In other words, these herbivores will be affected indirectly by climate change due to changes in the suitability / quality of their food. The aim of this doctoral thesis was to discover the effects of climate change within the relationship of the butterfly Pieris napi and its host plant (Sinapis alba used here as host plant), including individual conditions (e.g. chemical compositions of plants; morphology, physiology of the butterfly) and behavior of female butterflies and larvae. In the first experiment, the influence of simulated climate change on the chemical composition of the plant Sinapis alba was investigated. The second experiment aimed to examine the influence of changes in plant composition on the butterfly P. napi. Glucosinolates (secondary compound of plants) are known to have an important effect on the preference and performance of herbivores. Therefore, in the third experiment, the impact of glucosinolates on the preference and performance of P. napi was investigated in order to see if these plant compounds had the most important influence on this butterfly. Furthermore, in the fourth experiment, it was explored whether there is a latitudinal gradient within the species´ responses to changes in its host plant. The fifth and last experiment aimed to examine, if there are general principles across species regarding indirect effects of climate change.
Climate change, simulated by different combinations of temperature and water regimes, had an effect on the plant chemistry. The combination of temperature and water availability changed plant composition substantially. Especially the amount of carbon and glucosinolates (here above all sinalbin) in S. alba plants varies between the different treatments and therefore between the different combinations of temperature and water regimes. Regarding glucosinolates, elevated temperatures increased their concentration in leaves, whereas water deficit in combination with higher temperature reversed this pattern. For carbon content, all plants, except those of the control group, showed a decreased amount of total carbon. However, simulated heat waves had no effect on plants, leading to the assumption that the plants were able to recover from heat stress sufficiently during the control phases. Changes in plant composition affected both larvae and females of the butterfly P. napi. Therefore, changed host-plant chemistry alters the plant quality for this herbivore, meaning that plants of different treatments represent different plant qualities defined by their composition. Females of P. napi may be able to differentiate between plant qualities and even show a direct preference. Therefore, glucosinolates seem to act as oviposition stimulants. However, preferring another plant quality with lower amount of glucosinolates suggest that females of this butterfly species were attracted by more than high levels of glucosinolates alone. Larvae fed with different plant qualities performed differently, indicated by smaller wings (lighter bodies) and prolonged development when fed with plants contained higher amount of the glucosinolate sinalbin. It can be assumed that a higher amount of sinalbin decreases the quality of the host plant and therefore lead to these responses. Probably larvae need to shift their resources from growth to detoxification and therewith survival. Furthermore, drought conditions during plant growth seem to reduce the overall negative effects of higher temperatures, lead to an increase of host plant quality. Larvae seem to benefit from feeding on these “double-stressed” plants. Comparison between the results of the preference and performance tests suggests that there might be a mismatch between female preference and larval performance. It seems that the stimulating effect of high concentration of glucosinolates, in this case sinalbin, misdirects females´ decision to less suitable host plants, meaning that the advantage of less competition for larvae come at costs through detoxification. Using Brassica napus plants with genetically fixed glucosinolate levels, it could be demonstrate that there must be other plant components influencing females´ oviposition behavior been seen in the choice experiment with S. alba. The comparison of German and Italian populations to changes in host-plant quality showed fewer differences between countries as expected. However, German and Italian individuals differed in their reaction to altered plant quality, at least in developmental time and larval growth rate. It seems that Italian larvae benefitted from plants grown under higher temperatures, whereas drought-stressed plants affected them negatively. German individuals in contrast seem to benefit only from water stress during plant growth. With regard to the sexes of P. napi, it seems that females respond differently than males to changes in plant quality. Furthermore, the results of the performance test on Bicyclus anynana showed that there might be some general principles for the respond of butterflies to changes of its host plant. B. anynana responded in a similar way to different host plant qualities as P. napi did, meaning that plants grown under higher temperatures and drought conditions seem to be beneficial for the larval performance.
In summary, these findings may have important implications for the indirect effects of climate change on this butterfly in natural environments. First, climate change seems to have an impact on the chemical composition of plants. Second, changes in plants caused by increasing temperature and droughts seem to influence the preference and performance of this butterfly. However, there are differences between populations, which seem to be induced by former adaptation. And third, there might be some general principles for the respond of butterflies to changes in their host plants. This thesis focuses only on possible indirect effects of climate change. However, there are direct effects, which may alter the responses of herbivores to changes in their host plant as well. Therefore, further investigations in this linkage and in other plant-herbivore relationships will be necessary to explore how climate change may alter the relationship between herbivores and their hosts.